从泡状细胞触发的植物运动中学习：仿生细胞致动器。

Learning from plant movements triggered by bulliform cells: the biomimetic cellular actuator.

作者信息

Mader Anja, Langer Max, Knippers Jan, Speck Olga

机构信息

Institute of Building Structures and Structural Design (ITKE), University of Stuttgart, Stuttgart, Germany.

Plant Biomechanics Group, Botanic Garden, Faculty of Biology, University of Freiburg, Freiburg, Germany.

出版信息

J R Soc Interface. 2020 Aug;17(169):20200358. doi: 10.1098/rsif.2020.0358. Epub 2020 Aug 26.

DOI:10.1098/rsif.2020.0358

PMID:32842889

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7482577/

Abstract

Within the framework of a biomimetic top-down approach, our study started with the technical question of the development of a hinge-free and compliant actuator inspired by plant movements. One meaningful biological concept generator was the opening and closing movements of the leaf halves of grasses. Functional morphological investigations were carried out on the selected model plant . The results formed the basis for further clarifying the functional movement principle with a particular focus on the role of turgor changes in bulliform cells on kinetic amplification. All findings gained from the investigations of the biological model were incorporated into a finite-element analysis, as a prerequisite for the development of a pneumatic cellular actuator. The first prototype consisted of a row of single cells positioned on a plate. The cells were designed in such a way that the entire structure bent when the pneumatic pressure applied to each individual cell was increased. The pneumatic cellular actuator thus has the potential for applications on an architectural scale. It has subsequently been integrated into the midrib of the facade shading system Flectofold in which the bending of its midrib controls the hoisting of its wings.

摘要

在仿生自上而下方法的框架内，我们的研究始于一个技术问题，即开发一种受植物运动启发的无铰链且柔顺的致动器。一个有意义的生物概念生成器是草叶两半的开合运动。对选定的模式植物进行了功能形态学研究。这些结果为进一步阐明功能运动原理奠定了基础，特别关注泡状细胞膨压变化在动力学放大中的作用。从生物模型研究中获得的所有发现都被纳入有限元分析，这是开发气动细胞致动器的先决条件。第一个原型由一排位于板上的单个细胞组成。这些细胞的设计方式是，当施加到每个单独细胞的气压增加时，整个结构会弯曲。因此，气动细胞致动器具有在建筑规模上应用的潜力。它随后被集成到立面遮阳系统Flectofold的中肋中，其中中肋的弯曲控制着其翼片的升起。

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